Communication pubs.acs.org/JACS
Tyrosine Deprotonation Yields Abundant and Selective Backbone Cleavage in Peptide Anions upon Negative Electron Transfer Dissociation and Ultraviolet Photodissociation Jared B. Shaw,† Aaron R. Ledvina,† Xing Zhang,‡ Ryan R. Julian,‡ and Jennifer S. Brodbelt*,† †
Department of Chemistry and Biochemistry, The University of Texas at Austin, Austin, Texas 78712, United States Department of Chemistry, University of California, Riverside, California 92521, United States
‡
S Supporting Information *
mode analyses16,17 provide complementary information to that obtained in the positive ion mode, and the combined data sets allow more comprehensive proteomics analyses by MS/MS. However, CID of peptide anions is generally ineffective due to extensive and uninformative neutral losses.18,19 Recently, a number of dissociation methods including electron detachment dissociation (EDD),20,21 negative electron transfer dissociation (NETD),22,23 ultraviolet photodissociation (UVPD)24 at 193 nm, negative-ion ECD,25 and electron photodetachment dissociation (EPD)26−28 have been shown to be viable alternatives to CID for peptide anion characterization. Higher pH conditions using basic mobile phases for LC-MS enhance deprotonation of peptide sites not routinely deprotonated (e.g., tyrosine side chain with pKa ≈ 10). Deprotonation of alternative sites may promote alternative fragmentation pathways as described herein. We report preferential cleavage N-terminal to deprotonated tyrosine residues in peptide anions upon UVPD at 193 nm or upon NETD. The dominant backbone cleavages of peptide anions upon NETD21,22 typically result in a•- and x-type product ions and upon UPVD23 a- and x-type with lower levels of b, c, y, Y, and z ions. Conversely, NETD (Figure 1A), NETD with simultaneous IR photoactivation (a process termed AINETD) (Figure 1B), and UVPD (Figure 1C) of triply deprotonated DRVYIHPFHLVIHN yield abundant c3 and z11• ions which arise uniquely from cleavage N-terminal to the tyrosine residue. This process is likewise notable upon NETD and UVPD of the 3− charge states of peptides NEKYAQAYPNVS, Ac-DRVYIHPFHLVIHN, DRVYIHPFHLLVYS, and KTMTESSFYSNMLA (not shown). The formation of high-abundance c- and z-type product ions has not been reported previously for NETD or UVPD at 193 nm; however, the highly selective nature of the fragmentation suggests that a favorable radical-directed cleavage process may occur upon electron detachment from tyrosine-containing peptides. The electron−hole recombination energy upon electron transfer from peptide anions to fluoranthene radical cations has been previously estimated to be 2.5−4.5 eV on the basis of the difference in ionization energy (IE) of fluoranthene (IE = 7.9 eV) and the electron affinities (EA) of carboxylate (EA = 3.4 eV) and phosphate (EA = 5.4 eV) groups in phosphopeptides.23 The energy of a 193 nm photon is 6.4 eV. In a recent
ABSTRACT: Tyrosine deprotonation in peptides yields preferential electron detachment upon NETD or UVPD, resulting in prominent N−Cα bond cleavage N-terminal to the tyrosine residue. UVPD of iodo-tyrosine-modified peptides was used to generate localized radicals on neutral tyrosine side chains by homolytic cleavage of the C−I bond. Subsequent collisional activation of the radical species yielded the same preferential cleavage of the adjacent N-terminal N−Cα bond. LC-MS/MS analysis of a tryptic digest of BSA demonstrated that these cleavages are regularly observed for peptides when using high-pH mobile phases.
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ottom-up workflows for qualitative and quantitative protein identification utilizing liquid chromatography tandem mass spectrometry (LC-MS/MS) have emerged as one of the top technologies of choice for proteome analyses.1 The success of these strategies hinges upon the ability to accurately predict fragmentation patterns of theoretical peptide sequences generated in silico from protein sequence databases.2,3 The benchmark for peptide cation dissociation is collision-induced dissociation (CID);4,5 electron capture dissociation (ECD)6,7 and electron transfer dissociation (ETD)8,9 afford complementary information to CID and enhanced identification of labile post-translational modifications (PTMs).10 The dissociation mechanisms and characteristic product ion types of these methods have been investigated in depth and are fairly well understood. A number of preferential cleavage types have been reported for peptide cations. For example, cleavages at protonated histidine and Nterminal to proline residues are commonly observed upon CID of protonated peptides, and in the absence of a mobile proton, enhanced cleavage also occurs at the amide bond immediately C-terminal to acidic residues.11,12 Disulfide bond cleavage in multiply charged peptide and protein cations upon ECD and ETD is readily observed and for lower charge states is more favored than peptide/protein backbone cleavage.13−15 Exploration of the negative ion mode for protein identification affords an attractive alternative due to the fact that a large portion of biologically significant PTMs, such as phosphorylation, sulfonation, nitration, and glycosylation with acidic glycans, as well as many naturally occurring peptides and proteins, are acidic and thus readily form anions. Negative ion © XXXX American Chemical Society
Received: April 3, 2012
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dx.doi.org/10.1021/ja3032086 | J. Am. Chem. Soc. XXXX, XXX, XXX−XXX
Journal of the American Chemical Society
Communication
yields results entirely consistent with the previously proposed mechanism (Figure S2). The substantially increased abundances of the c3 and z11• ions upon NETD with simultaneous IR photoactivation (Figure 1B) compared to NETD alone (Figure 1A) suggests that the additional vibrational energy provided by IR photoactivation allows a greater portion of tyrosyl radical ions to undergo the radical migration/N−Cα backbone cleavage process. CID of the charge-reduced precursor ([M − 3H]2−•) produced by NETD (Figure 2A) or by UVPD (Figure 2B) of triply deprotonated DRVYIHPFHLVIHN yields the same abundant c3 and z11• ions along with neutral losses of water, carbon dioxide, and tyrosine side chain. This indicates that a
Figure 1. (A) NETD, (B) NETD with simultaneous IR photoactivation, and (C) UVPD spectra of triply deprotonated DRVYIHPFHLVIHN. * and ’ represent the precursor and loss of water, respectively. Figure 2. MS3 spectrum upon CID of the charge-reduced precursor ([M − 3H]2−•) produced by (A) NETD and (B) UVPD of triply deprotonated DRVYIHPFHLVIHN . * and ’ represent the precursor and loss of water, respectively.
top-down EDD study, Breuker et al. tabulated the EA of radical functional groups in peptides and proteins.29 The EA of each radical functional group is equivalent to the IE of the corresponding deprotonated functional group, and all are